Research ArticlesNo Access

Formulation and Implementation of Nonlinear Integral Equations to Model Neural Dynamics Within the Vertebrate Retina

Jason K. Eshraghian

School of Electrical, Electronic and Computer Engineering, University of Western Australia, Crawley, Australia

E-mail Address: jason.eshraghian@research.uwa.edu.au

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Seungbum Baek

College of Electrical and Computer Engineering, Chungbuk National University, Cheongju, Republic of Korea

E-mail Address: sbbaek@cbnu.ac.kr

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Jun-Ho Kim

College of Electrical and Computer Engineering, Chungbuk National University, Cheongju, Republic of Korea

E-mail Address: jhkim90@cbnu.ac.kr

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Nicolangelo Iannella

School of Mathematical Sciences, University of Nottingham, NG7 2RD, UK

E-mail Address: nicolangelo.iannella@notthingham.ac.uk

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Kyoungrok Cho

College of Electrical and Computer Engineering, Chungbuk National University, Cheongju, Republic of Korea

E-mail Address: krcho@cbnu.ac.kr

Corresponding author.

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Yong Sook Goo

Department of Physiology, School of Medicine, Chungbuk National University, Cheongju, Republic of Korea

E-mail Address: ysgoo@chungbuk.ac.kr

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Herbert H. C. Iu

School of Electrical, Electronic and Computer Engineering, University of Western Australia, Crawley, Australia

E-mail Address: herbert.iu@uwa.edu.au

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Sung-Mo Kang

Department of Electrical Engineering, University of California, Santa Cruz, Santa Cruz, USA

E-mail Address: skang@ucsc.edu

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, and

Kamran Eshraghian

iDataMap Corporation, Australia

E-mail Address: keshraghian@idatamap.com

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https://doi.org/10.1142/S0129065718500041Cited by:17 (Source: Crossref)

Abstract

Existing computational models of the retina often compromise between the biophysical accuracy and a hardware-adaptable methodology of implementation. When compared to the current modes of vision restoration, algorithmic models often contain a greater correlation between stimuli and the affected neural network, but lack physical hardware practicality. Thus, if the present processing methods are adapted to complement very-large-scale circuit design techniques, it is anticipated that it will engender a more feasible approach to the physical construction of the artificial retina. The computational model presented in this research serves to provide a fast and accurate predictive model of the retina, a deeper understanding of neural responses to visual stimulation, and an architecture that can realistically be transformed into a hardware device. Traditionally, implicit (or semi-implicit) ordinary differential equations (OES) have been used for optimal speed and accuracy. We present a novel approach that requires the effective integration of different dynamical time scales within a unified framework of neural responses, where the rod, cone, amacrine, bipolar, and ganglion cells correspond to the implemented pathways. Furthermore, we show that adopting numerical integration can both accelerate retinal pathway simulations by more than 50% when compared with traditional ODE solvers in some cases, and prove to be a more realizable solution for the hardware implementation of predictive retinal models.

Keywords:

References

1. W. H. Dobelle, Artificial vision for the blind by connecting a television camera to the visual cortex, Am. Soc. Artif. Intern. Organs J. 46(1) (2000) 3–9. Crossref, Google Scholar
2. C. A. Curcio, K. R. Sloan, R. E. Kalina and A. E. Hendrickson, Human photoreceptor topography, J. Comp. Neurol. 292(4) (1990) 497–523. Crossref, Medline, Web of Science, Google Scholar
3. J. G. Nicholls, A. R. Martin, B. G. Wallace and P. A. Fuchs (eds.), From Neuron to Brain (Sinauer Associates, Sunderland, 2001). Google Scholar
4. R. H. Masland, The fundamental plan of the retina, Nat. Neurosci. 4(9) (2001) 877–886. Crossref, Medline, Web of Science, Google Scholar
5. G. Auda and M. Kamel, Modular neural networks: A survey, Int. J. Neural Syst. 9(2) (1999) 129–151. Link, Google Scholar
6. E. Moisseiev and M. J. Mannis, Evaluation of a portable artificial vision device among patients with low vision, JAMA Ophthalmol. 134(7) (2016) 748–752. Crossref, Medline, Web of Science, Google Scholar
7. J. D. Weiland, S. T. Walston and M. S. Humayun, Electrical stimulation of the retina to produce artificial vision, Annu. Rev. Vis. Sci. 2 (2016) 273–294. Crossref, Medline, Web of Science, Google Scholar
8. D. A. X. Nayagam, C. McGowan, J. Villalobos, R. A. Williams, C. Salinas-LaRosa, P. McKelvie, I. Lo, M. Basa, J. Tan and C. E. Williams, Techniques for processing eyes implanted with a retinal prosthesis for localized histopathological analysis, J. Vis. Exp. 78 (2013) e50411. Google Scholar
9. K. Stingl, K. U. Bartz-Schmidt, D. Besch, A. Braun, A. Bruckmann, F. Gekeler, U. Greppmaier, S. Hipp, G. Hortdorfer, C. Kernstock, A. Koitschev, A. Kusnyerik, H. Sachs, A. Schatz, K. T. Stingl, T. Peters, B. Wilhelm and E. Zrenner, Artificial vision with wirelessly powered subretinal electronic implant alpha-IMS, Proc. Royal Soc. B 280(1757) (2013) 20130077. Crossref, Medline, Web of Science, Google Scholar
10. M. Waisbourd, O. Ahmed, L. Siam, M. R. Moster, L. A. Hark and L. J. Katz, The impact of a novel artificial vision device (OrCam) on the quality of life of patients with end-stage glaucoma, Invest. Ophthalmol. Vis. Sci. 56(7) (2015) 519. Google Scholar
11. S. Shirmohammadi and A. Ferrero, Camera as the instrument: The rising trend of vision based measurement, IEEE Instrum. Meas. Mag. 17(3) (2014) 41–47. Google Scholar
12. H. Ji and P. A. Abshire, Fundamentals of silicon-based phototransduction, CMOS Imagers from Phototransduction to Image Processing, eds. O. Yadid-Pecht and R. Etienne-Cummings (Springer Science & Business Media, New York, 2007), pp. 1–51. Google Scholar
13. A. J. P. Theuwissen, CMOS image sensors: State-of-the-art, Solid-State Electron. 52(9) (2008) 1401–1406. Crossref, Web of Science, Google Scholar
14. J. J. Gibson (ed.), The Perception of the Visual World (Houghton Mifflin, Boston, 1950). Google Scholar
15. P. R. G. V. Bruce and M. A. Georgeson (eds.), Visual Perception: Physiology, Psychology, & Ecology (Psychology Press, Hove, 2003). Google Scholar
16. T. Cornsweet (ed.), Visual Perception (Academic Press, Cambridge, 2012). Google Scholar
17. A. Destexhe and T. J. Sejnowski, Thalamocortical Assemblies: How Ion Channels, Single Neurons and Large-Scale Networks Organize Sleep Oscillations (Oxford University Press, 2001). Google Scholar
18. A. L. Hodgkin and A. F. Huxley, A quantitative description of membrane current and its application to conduction and excitation in nerve, J. Physiol. 117(4) (1952) 500–544. Crossref, Medline, Web of Science, Google Scholar
19. P. Martínez-Cañada, C. Morillas, B. Pino, E. Ros and F. Pelayo, A computational framework for realistic retina modeling, Int. J. Neural Syst. 26(7) (2016) 1650030. Link, Web of Science, Google Scholar
20. A. Ferscha and S. K. Tripathi, Parallel and distributed simulation of discrete event systems, Technical Report, University of Vienna (Vienna, Austria, 1994). Google Scholar
21. P. M. Sloot, J. Kaandorpa, A. G. Hoekstra and B. J. Overeinder, Distributed simulation with cellular automata: Architecture and applications, Int. Conf. Curr. Trends in Theory and Practice of Computer Science (Milovy, Czech Republic, 1999), pp. 203–248. Google Scholar
22. R. M. Fujimoto, Parallel and Distributed Simulation Systems (Wiley, New York, 2000). Google Scholar
23. B. P. Zeigler, H. Praehofer and T. G. Kim, Theory of Modeling and Simulation: Integrating Discrete Event and Continuous Complex Dynamic Systems (Academic Press, Cambridge, 2000). Google Scholar
24. G. Lee and N. H. Farhat, The double queue method: A numerical method for integrate-and-fire neuron networks, Neural Netw. 14(6) (2001) 921–932. Crossref, Medline, Web of Science, Google Scholar
25. H. Momiji, A. A. Bharath, M. W. Hankins and C. Kennard, Numerical study of short-term after images and associate properties in foveal vision, Vis. Res. 46(3) (2006) 365–381. Crossref, Medline, Web of Science, Google Scholar
26. H. Momiji, M. W. Hankins, A. A. Bharath and C. Kennard, A numerical study of red–green colour opponent properties in the primate retina, Eur. J. Neurosci. 25(4) (2007) 1155–1165. Crossref, Medline, Web of Science, Google Scholar
27. S. Bibyk and M. Ismail, Issues in analog VLSI and MOS techniques for neural computing, Analog VLSI Implementation of Neural Systems, eds. C. Mead and M. Ismail, Vol. 80 (Springer Science & Business Media, New York, 2012). Google Scholar
28. J. Schemmel, J. Fieres and K. Meier, Wafer-scale integration of analog neural networks, IEEE Int. Joint Conf. Neural Networks (Hong Kong, 2008), pp. 431–438. Google Scholar
29. G. Trucco and V. Liberali, Analog design issues for mixed-signal CMOS integrated circuits, in Advances in Analog Circuits, ed. EstebanTlelo-Cuautle (InTech, London, United Kingdom, 2011), p. 165. Crossref, Google Scholar
30. K. Cho, S. Baek, S.-W. Cho, J.-H. Kim, Y. S. Goo, J. K. Eshraghian, N. Iannella and K. Eshraghian, Signal flow platform for mapping and simulation of vertebrate retina for sensor systems, IEEE Sens. J. 16(15) (2016) 5856–5866. Crossref, Web of Science, Google Scholar
31. J. K. Eshraghian, S. Baek, K. Cho, N. Iannella, J.-H. Kim, Y. S. Goo, H. H. C. Iu, T. Fernando and K. Eshraghian, Modelling and analysis of signal flow platform implementation into retinal cell pathway, IEEE Asia Pacific Conf. Circ. Syst. (Jeju, South Korea, 2016), pp. 491–494. Google Scholar
32. S. Draghici, Neural networks in analog hardware — Design and implementation issues, Int. J. Neural Syst. 10(1) (2000) 19–42. Link, Google Scholar
33. M. Tessier-Lavigne and D. Attwell, The effect of photoreceptor coupling and synapse nonlinearity on signal: Noise ratio in early visual processing, Proc. R. Soc. B Biol. Sci. 234(1275) (1988) 171–197. Crossref, Medline, Web of Science, Google Scholar
34. J. Zhang and S. M. Wu, Physiological properties of rod photoreceptor electrical coupling in the tiger salamander retina, J. Physiol. 564(3) (2005) 849–862. Crossref, Medline, Web of Science, Google Scholar
35. H. von Gersdorff, Synaptic ribbons: Versatile signal transducers, Neuron 29(1) (2001) 7–10. Crossref, Medline, Web of Science, Google Scholar
36. L. Lagnado, Ribbon synapses, Curr. Biol. 13(16) (2003) R631. Crossref, Medline, Web of Science, Google Scholar
37. M. H. Hennig, K. Funke and F. Wörgötter, The influence of different retinal subcircuits on the nonlinearity of ganglion cell behavior, J. Neurosci. 22(19) (2002) 8726–8738. Crossref, Medline, Web of Science, Google Scholar
38. M. H. Hennig and F. Wörgötter, Effects of fixational eye movements on retinal ganglion cell responses: A modelling study, Front. Comput. Neurosci. 1 (2007) 1–12. Crossref, Medline, Web of Science, Google Scholar
39. H. Kolb and E. V. Famigilietti, Rod and cone pathways in the inner plexiform layer of cat retina, Science 186(4158) (1974) 47–49. Crossref, Medline, Web of Science, Google Scholar
40. R. E. Marc, J. R. Anderson, B. W. Jones, C. L. Sigulinsky and J. S. Lauritzen, The AII amacrine cell connectome: A dense network hub, Front. Neural Circuits 8(104) (2014) 1–13. Medline, Web of Science, Google Scholar
41. A. Wohrer and P. Kornprobst, Virtual retina: A biological retina model and simulator, with contrast gain control, J. Comput. Neurosci. 26(2) (2009) 219–249. Crossref, Medline, Web of Science, Google Scholar
42. C. Enroth-Cugell, J. Robson, D. Schweitzer-Tong and A. Watson, Spatio-temporal interactions in cat retinal ganglion cells showing linear spatial summation, J. Physiol. 341 (1983) 279–307. Crossref, Medline, Web of Science, Google Scholar
43. D. Cai, G. C. Deangelis and R. D. Freeman, Spatiotemporal receptive field organization in the lateral geniculate nucleus of cats and kittens, J. Neurophysiol. 78(2) (1997) 1045–1061. Crossref, Medline, Web of Science, Google Scholar
44. C. A. Mead and M. A. Mahowald, A silicon model of early visual processing, Neural Netw. 1(1) (1988) 91–97. Crossref, Web of Science, Google Scholar
45. J. Hérault, A model of colour processing in the retina of vertebrates: From photoreceptors to colour opposition and colour constancy phenomena, Neurocomputing 12(2) (1996) 113–129. Crossref, Web of Science, Google Scholar
46. R. Publio, R. F. Oliveira and A. C. Roque, A computational study on the role of gap junctions and rod $I_{h}$ conductance in the enhancement of the dynamic range of the retina, PLoS ONE 4(9) (2009) e6970. Crossref, Medline, Web of Science, Google Scholar
47. Y. Kamiyama, S. M. Wu and S. Usui, Simulation analysis of bandpass filtering properties of a rod photoreceptor network, Vis. Res. 49(9) (2009) 970–978. Crossref, Medline, Web of Science, Google Scholar
48. K. Loizos, G. Lazzi, J. S. Lauritzen, J. Anderson, B. W. Jones and R. Marc, A multi-scale computational model for the study of retinal prosthetic stimulation, 36th Annual Int. Conf. IEEE Engineering in Medicine and Biology Society, (Chicago, IL, USA, 2014), pp. 6100–6103. Google Scholar
49. M. D. Archer, Genesis of the Nernst Equation (ACS Publications, Washington DC, 1989). Crossref, Google Scholar
50. F. Helmchen, J. Borst and B. Sakmann, Calcium dynamics associated with a single action potential in a cns presynaptic terminal, Biophys. J. 72(3) (1997) 1458–1471. Crossref, Medline, Web of Science, Google Scholar
51. R. D. Traub and R. Wong, Synchronized burst discharge in disinhibited hippocampal slice. ii. model of cellular mechanism, J. Neurophysiol. 49(2) (1983) 459–471. Crossref, Medline, Web of Science, Google Scholar
52. A. Destexhe, A. Babloyantz and T. J. Sejnowski, Ionic mechanisms for intrinsic slow oscillations in thalamic relay neurons, Biophys. J. 65(4) (1993) 1538–1552. Crossref, Medline, Web of Science, Google Scholar
53. X.-J. Wang, Calcium coding and adaptive temporal computation in cortical pyramidal neurons, J. Neurophysiol. 79(3) (1998) 1549–1566. Crossref, Medline, Web of Science, Google Scholar
54. Y.-H. Liu and X.-J. Wang, Spike-frequency adaptation of a generalized leaky integrate-and-fire model neuron, J. Comput. Neurosci. 10(1) (2001) 25–45. Crossref, Medline, Web of Science, Google Scholar
55. D. A. McCormick and J. R. Huguenard, A model of the electrophysiological properties of thalamocortical relay neurons, J. Neurophysiol. 68(4) (1992) 1384–1400. Crossref, Medline, Web of Science, Google Scholar
56. R. C. O’Reilly, Biologically based computational models of high-level cognition, Science 314(5796) (2006) 91–94. Crossref, Medline, Web of Science, Google Scholar
57. F. Sala and A. Hernandez-Cruz, Calcium diffusion modeling in a spherical neuron. Relevance of buffering properties, Biophys. J. 57(2) (1990) 313–324. Crossref, Medline, Web of Science, Google Scholar
58. B. Hille (ed.), Ion Channels of Excitable Membranes (Sinauer Associates, Sunderland, 2001). Google Scholar
59. D. Johnston, S. M.-S. Wu and R. Gray (eds.), Foundations of Cellular Neurophysiology (MIT Press, Cambridge, 1995). Google Scholar
60. T. F. Weiss (ed.), Cellular Biophysics (The MIT Press, Cambridge, MA, USA, 1996). Google Scholar
61. J. Eshraghian, Mathematical model of retinal cells, 2017, Appendix, http://ccns.cbnu.ac.kr/paper/1605/appendix.pdf. Google Scholar
62. L. Abbott and E. Marder, Modeling small networks, Methods in Neuronal Modeling, eds. C. Koch and I. Segev (MIT Press, Cambridge, 1998), pp. 361–410. Google Scholar
63. L. Abbott and T. Kepler, Model neurons: From Hodgkin-Huxley to Hopfield, in Statistical Mechanics of Neural Network (1990), pp. 5–18. Crossref, Google Scholar
64. T. B. Kepler, L. Abbott and E. Marder, Reduction of conductance-based neuron models, Biol. Cybern. 66(5) (1992) 381–387. Crossref, Medline, Web of Science, Google Scholar
65. C. Koch (ed.), Biophysics of Computation: Information Processing in Single Neurons (Oxford University Press, Oxford, 1998). Crossref, Google Scholar
66. B. A. Cohn, S. P. Collin, P. C. Wainwright and L. Schmitz, Retinal topography maps in R: New tools for the analysis and visualization of spatial retinal data, J. Vision 15(9) (2015) 19–29. Crossref, Medline, Web of Science, Google Scholar
67. H. Asari and M. Meister, Divergence of visual channels in the inner retina, Nat. Neurosci. 15(11) (2012) 1581–1589. Crossref, Medline, Web of Science, Google Scholar
68. D. Hillier, M. Fiscella, A. Drinnenberg, S. Trenholm, S. B. Rompani, Z. Raics, G. Katona, J. Juettner, A. Hierlemann, B. Rozsa et al., Causal evidence for retina-dependent and-independent visual motion computations in mouse cortex, Nat. Neurosci. 20 (2017) 960–968. Crossref, Medline, Web of Science, Google Scholar
69. D. Baylor and B. Nunn, Electrical properties of the light-sensitive conductance of rods of the salamander ambystoma tigrinum, J. Physiol. 371 (1986) 115–145. Crossref, Medline, Web of Science, Google Scholar
70. S. Forti, A. Menini, G. Rispoli and V. Torre, Kinetics of phototransduction in retinal rods of the newt triturus cristatus, J. Physiol. 419(1) (1989) 265–295. Crossref, Medline, Web of Science, Google Scholar
71. Y. Kamiyama, T. Ogura and S. Usui, Ionic current model of the vertebrate rod photoreceptor, Vis. Res. 36(24) (1996) 4059–4068. Crossref, Medline, Web of Science, Google Scholar
72. D. Baylor, A. Hodgkin and T. Lamb, The electrical response of turtle cones to flashes and steps of light, J. Physiol. 242(3) (1974) 685–727. Crossref, Medline, Web of Science, Google Scholar
73. S. Usui, A. Ishihaiza, Y. Kamiyama and H. Ishii, Ionic current model of bipolar cells in the lower vertebrate retina, Vis. Res. 36(24) (1996) 4069–4076. Crossref, Medline, Web of Science, Google Scholar
74. R. G. Smith and N. Vardi, Simulation of the AII amacrine cell of mammalian retina: Functional consequences of electrical coupling and regenerative membrane properties, Vis. Neurosci. 12(5) (1995) 851–860. Crossref, Medline, Web of Science, Google Scholar
75. J. Fohlmeister and R. Miller, Impulse encoding mechanisms of ganglion cells in the tiger salamander retina, J. Neurophysiol. 78(4) (1997) 1935–1947. Crossref, Medline, Web of Science, Google Scholar
76. J. Fohlmeister, P. Coleman and R. Miller, Modeling the repetitive firing of retinal ganglion cells, Brain Res. 510(2) (1990) 343–345. Crossref, Medline, Web of Science, Google Scholar
77. N. Kopell and B. Ermentrout, Chemical and electrical synapses perform complementary roles in the synchronization of interneuronal networks, Proc. Natl. Acad. Sci. USA 101(43) (2004) 15482–15487. Crossref, Medline, Web of Science, Google Scholar
78. S. Curti and J. O’Brien, Characteristics and plasticity of electrical synaptic transmission, BMC Cell Biol. 17(1) (2016) 13. Crossref, Medline, Google Scholar
79. N. H. Weste and K. Eshraghian (eds.), Principles of CMOS VLSI Design (Addison-Wesley, Boston, 1993). Google Scholar
80. L. Greengard and V. Rokhlin, A fast algorithm for particle simulations, J. Comput. Phys. 73(2) (1987) 325–348. Crossref, Web of Science, Google Scholar
81. K. Saladin (ed.), Anatomy & Physiology: The Unity of Form and Function (McGraw-Hill Higher Education, New York, 1997). Google Scholar
82. S. Ghosh-Dastidar and H. Adeli, Spiking neural networks, Int. J. Neural Syst. 19(4) (2009) 295–308. Link, Web of Science, Google Scholar
83. G. Tosini, N. Pozdeyev, K. Sakamoto and P. M. Iuvone, The circadian clock system in the mammalian retina, BioEssays 30(7) (2008) 624–633. Crossref, Medline, Web of Science, Google Scholar
84. P. Sterling, M. A. Freed and R. G. Smith, Architecture of rod and cone circuits to the on-beta ganglion cell, J. Neurosci. 8(2) (1988) 623–642. Crossref, Medline, Web of Science, Google Scholar
85. L. F. Shampine and M. W. Reichelt, The MATLAB ODE Suite, SIAM J. Sci. Comput. 18(1) (1997) 1–22. Crossref, Web of Science, Google Scholar
86. J. C. Butcher (ed.), The Numerical Analysis of Ordinary Differential Equations: Runge–Kutta and General Linear Methods (Wiley-Interscience, New York, 1987). Google Scholar
87. R. H. Cameron, A “Simpson’s Rule” for the numerical evaluation of Wiener’s integrals in function space, Duke Math. J. 18(1) (1951) 111–130. Crossref, Web of Science, Google Scholar
88. J. C. Butcher, Numerical Methods for Ordinary Differential Equations, 3rd edn. (John Wiley & Sons, Hoboken, 2016). Crossref, Google Scholar
89. W. E. Milne, Numerical integration of ordinary differential equations, Am. Math. Mon. 33(9) (1926) 455–460. Crossref, Google Scholar
90. A. Lasansky, Lateral contacts and interactions of horizontal cell dendrites in the retina of the larval tiger salamander, J. Physiol. 301 (1980) 59. Crossref, Medline, Web of Science, Google Scholar
91. D. Purves, G. J. Augustine, D. Fitzpatrick, L. C. Katz, A.-S. LaMantia, J. O. McNamara and S. M. Williams, Anatomical Distribution of Rods and Cones (Sinauer Associates, Sunderland, 2001). Google Scholar
92. J. B. Jonas, U. Schneider and G. O. Naumann, Count and density of human retinal photoreceptors, Graefe’s Arch. Clin. Exp. Ophthalmol. 230(6) (1992) 505–510. Crossref, Medline, Web of Science, Google Scholar
93. D. J. Margolis and P. B. Detwiler, Different mechanisms generate maintained activity in on and off retinal ganglion cells, J. Neurosci. 27(22) (2007) 5994–6005. Crossref, Medline, Web of Science, Google Scholar
94. T. Kameneva, H. Meffin and A. N. Burkitt, Modelling intrinsic electrophysiological properties of on and off retinal ganglion cells, J. Comp. Neurosci. 31(3) (2011) 547–561. Crossref, Medline, Web of Science, Google Scholar
95. T. Launey, A computational approach to the study of AMPA receptor clustering at purkinje cell synapses, Arch. Ital. Biol. 145(3) (2007) 299–310. Medline, Web of Science, Google Scholar